T. Alexander Dececchievolution. Amongst smaller bodied taxa the competing pressures of being both a...
Transcript of T. Alexander Dececchievolution. Amongst smaller bodied taxa the competing pressures of being both a...
The fast and the frugal: Divergent locomotory strategies drive limb lengthening in theropod
dinosaurs
T. Alexander Dececchi1,*, Aleksandra M. Mloszewska, Thomas R. Holtz Jr.3,4, Michael B. Habib5, Hans C.E. Larsson6 1T. Alexander Dececchi, Department of Biology, Division of Natural Sciences, Mount Marty College, Yankton, South Dakota, United States of America. 2 397 Winchester Avenue, Sudbury ON, [email protected] 3 Department of Geology, University of Maryland, College Park, Maryland, United States of America. 4 Department of Paleobiology, National Museum of Natural History, Washington, DC, United States of America. 5Integrative Anatomical Sciences, Keck School of Medicine of USC, University of Southern California, Los Angeles, California, United States of America. 6Redpath Museum, McGill University, Montreal, Quebec, Canada. *Corresponding author: [email protected] Abstract Limb length, cursoriality and speed have long been areas of significant interest in theropod
paleobiology as locomotory capacity, especially running ability, is critical in not just in prey
pursuit but also to avoid become prey oneself. One aspect that is traditionally overlooked is the
impact of allometry on running ability and the limiting effect of large body size. Since several
different non-avian theropod lineages have each independently evolved body sizes greater than
any known terrestrial carnivorous mammal, ~1000kg or more, the effect that such larger mass
has on movement ability and energetics is an area with significant implications for Mesozoic
paleoecology. Here using expansive datasets, incorporating several different metrics to estimate
body size, limb length and running speed, to calculate the effects of allometry running We test
both on traditional metrics used to evaluate cursoriality in non-avian theropods such as distal
limb length, relative hindlimb length as well as comparing the energetic cost savings of relative
hindlimb elongation between members of the Tyrannosauridae and more basal megacarnivores
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such as Allosauroids or Ceratosauridae. We find that once the limiting effects of body size
increase is incorporated, no commonly used metric including the newly suggested distal limb
index (Tibia + Metatarsus/ Femur length) shows a significant correlation to top speed. The data
also shows a significant split between large and small bodied theropods in terms of maximizing
running potential suggesting two distinct strategies for promoting limb elongation based on the
organisms’ size. For small and medium sized theropods increased leg length seems to correlate
with a desire to increase top speed while amongst larger taxa it corresponds more closely to
energetic efficiency and reducing foraging costs. We also find, using 3D volumetric mass
estimates, that the Tyrannosauridae show significant cost of transport savings compared to more
basal clades, indicating reduced energy expenditures during foraging and likely reduced need for
hunting forays. This suggests that amongst theropods while no one strategy dictated hindlimb
evolution. Amongst smaller bodied taxa the competing pressures of being both a predator and a
prey item dominant while larger ones, freed from predation pressure, seek to maximize foraging
ability. We also discuss the implications both for interactions amongst specific clades and
Mesozoic paleobiology and paleoecological reconstructions as a whole.
Introduction
Non-avian theropod dinosaurs were the dominant terrestrial carnivores during much of the
Mesozoic. They occupied much of the available niche space [1-3], and ranged in size from
<200g to approximately 9000kg [4, 5]. While no single adaptation is likely to explain such
widespread dominance and diversity of form, the bipedal locomotory system employed by
theropods is invoked as an important reason for the success of this lineage [6]. For animals, the
speed at which they travel is a critical factor in their survival strategy as it impacts all aspects of
food collection, dispersal, migration and predator avoidance [7]. Because of this, much work has
been done to model locomotion and how it affects different aspects of theropod life history and
behavior, such as movement efficiency, turning radius, balance [8-14]. Additionally, studies of
the growth across the clade, both ontogenetically and allometrically [15-18], have shown marked
difference in traditional markers for cursorial potential [14, 19] , such as interlimb ratios, lower
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limb length and relative total limb length. This includes comparisons of derived coelurosaurian
theropods at all body sizes to more basal clades, and have been suggested to be linked to a
refinement of running ability in this group [8, 15, 19].
Recent work by Parson and Currie [14] attempted to further this by quantifying relative
cursoriality amongst non-avian theropods the use of the distal hind limb indices (tibia +
metatarsal length/ femur). They argued that the application of this metric could identify those
taxa with the highest top speed and attempted to establish that it had significant impact on the
ecological role and the diversification of theropods. Yet the challenge is that much of an
organisms locomotory repertoire, both in terms of percentage of behaviours and duration, is at
lower speeds[20], this is especially true in carnivores who often spend hours searching for or
pursuing prey and low to moderate speeds between bursts of high speed running[21, 22].
Without considering the fact that much of the energy budget and life history of a predator is
spent at lower gears, the relative speed of predators compared to suspected prey items and its
role in shaping the evolutionary landscape for theropods as well as the effect of other factors
such as body size in their analysis Parson and Currie may have overestimated the importance of
top speed.
Here we re-examine locomotion in non-avian theropods, applying indices based on estimates of
top speed and energetic expenditures to get a more complete sense of how differences in relative
limb lengths, and of components within the limb itself, reflect the paleobiology and paleoecology
of these creatures. Our goal is to more accurate understand the selective pressures that shaped
limb length and interlimb proportion evolution across theropods, and to compare how the
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evolution of extremely body size, greater than 1000 kg, may have altered the drivers for distal
limb indices. Through this we seek to more accurately reconstruct patterns of cursoriality and
foraging strategies amongst theropods and understand better how they shaped the ecosystems un
which they lived.
Materials
Relative leg length and max speed
Measurements of snout to vent length along with hindlimb lengths for 93 specimens for 71
different genera of avian and non-avian theropods were collected from the literature and personal
measurements (Sup. Table 1) that had at least one hindlimb element recorded. This included 82
specimens with a complete hindlimb preserved such that leg length and hip height could be
estimated and from that speed calculated (Sup. Table 2). Sampling includes members form all
major clades and multiple specimens per species, often from different ontogenetic stages, where
possible to capture the maximum diversity of Mesozoic theropod hindlimb disparity. These taxa
range in SVL size from 70 to over 5000 mm. A subset of this data, 22 non-avian theropods
where femoral circumferences were available, were selected to examine how body mass relates
to various metrics of leg elongation (Sup. Table 3). We only included non-avian theropods as
previous work has suggested significant allometric and functional shifts in the limbs of early
avians compared to their non-avian ancestors [15]. This dataset was then expanded to 77
specimens by including multiple taxa without SVL measurements to capture more non-avian
theropod diversity (Sup Table 4). We chose several different metrics to evaluate the connection
between hindlimb length and speed including total hindlimb length, distal hindlimb index and
hindlimb/ SVL, hindlimb length / m^1/3 and metatarsal length m^1/3 .
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To calculate maximal running speed, we used several estimators to be able to compare values
across proxies. The first is Froude number, which is a dimensionless number that allows for
relative size to be removed from velocity calculations [23] . The second is locomotor velocity,
which is calculated as
V=ÖFr / h*g [10].
Where v is the velocity in m/s, Fr=Froude number, h= hip height taken here as hindlimb length
and g is gravity. For hip height we chose to estimate it as 0.8 x total limb length, which
corresponds to the level of crouch seen in large terrestrial modern birds [24] and mimics the
values seen in other similar studies [10]. For taxa with a body mass of less than 1000kg we
calculated a range of Froude values from 0.25 to 15 to document behaviors from slow walk to
top speed while being within the range possible for both non-avian and avian theropods [11, 25-
27]. For larger taxa a maximum Froude number of 5 was used as this is suspected to be the limit
that they could achieve [10]. In addition to using Froude number we also calculated maximum
speed based on another methodology: the stride length based on either Alexander [28]
V=0.25 g 0.5 l1.67 h-1.17
Or the correction by Ruiz and Torices [29]
V=0.226 g 0.5 l1.67 h-1.17
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Where l is the relative stride length (RSL). We took for RSL values of 2 and 4.5 corresponding
to a slow and a fast burst run and within the range seen in theropod trackways [30] . Finally, we
used either published 3-D volumetric estimates of body mass,[9, 31, 32] or generated estimates
based on femoral circumference [33] to calculate top speed based on mass limiting factor [7].
This last value is grounded on extant taxa and suggests mass specific limitations on acceleration
and top speed, something seen in the modern realm but not factored in by our other metrics.
Energy consumption in large theropods
Estimates of energetic expenditure during foraging amongst the largest bodied theropods were
calculated from mass estimates based on several published 3-D body volume reconstructions,
one of the most a reliable and comparable method to estimate body mass [9, 10, 31, 32] (Table
1). The advantages of using 3D volumetric mass estimates to compare between taxa is that it is
an estimate generated using the an internally consistent, replicated and validated methodology
tailored for individual specimens and does not rely on hindlimb dimension, which we are using
in other aspects, thus preventing circularity in our arguments. This allows us to compare relative
elongation levels with an outside proxy and one that reduces the potential issue that even in the
most constrained size reconstruction from femoral length or circumference has the confidence
intervals that can span orders of magnitude in mass, thus making it extremely difficult to
determine if two taxa, even if they show similar values for said estimator, are actually similar in
body mass [33]. Since this is critical for this type of analysis, using more generalized body mass
figures obtained through femoral circumference as used in our previous section (Sup. Tables 3-5)
would be inadequate for the purposes used here. We attempted, whenever possible, to confine
our analysis to looking at taxa only with volumetric mass estimates taken from within the same
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study to ensure that differences in volumetric estimations methods do not cause spurious results.
When multiple masses were presented we chose to run our analysis using the “best estimate”
model as defined in the original papers for all specimens as opposed to the heaviest or lightest.
This was done so that we could get direct comparative data using the same variables and not bias
the results by artificially inflating or reducing the body mass volumes a priori. This model often
produces very similar mass estimates for these two specimens, such as between Tyrannosaurus
and Acrocanthosaurus using which differs only by 1.7% [32].
As a significant proportion of a predator’s daily activity budget is occupied by foraging [21,
22, 34, 35] we choose to reconstruct the energetics values based on cost of foraging [10] using an
absolute speed of 2 m/s to simulate a slow walk (Froude number <0.25). This is similar to the
estimate used by [35] and well within the walking range estimated from known trackways for
large theropods[36-42]. We then combined cost of transport (CoT) with a speed of transport to
calculated the costs to forage to both cover a set distance (18 km, the daily expected foraging
range of a large theropod [34] and 6570km which is the yearly total) as well as over a series of
time intervals ( 12 hours/ day foraging per [35] and 1 year) to examine the difference in
expenditures across comparable sized taxa.
Finally, to compare proportional expenditures we preformed two different analyses. First we
transformed the difference calculated in kilojoules (kj) into kilograms (kg) of meat by using the
energetic conversion values from [43] for large mammalian carnivores. While we understand
that the digestive and excretory methods of theropods make it difficult to estimate of the amount
of meat required, especially if they excreted uric acid like modern avians which leads to greater
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energy loss [43], regardless these parameters are similar to previous studies[35] and defendable
based on suspected aerobic capability [10]. In addition, previous work has suggested that the
largest theropods would have a metabolic rate equivalent of a 1000 kg carnivorous mammal [44],
which is approaching the theoretical maximum size for a terrestrial carnivore [21]. We also
compared expenditure values to estimates of Basal metabolic rate based on the equations of
McNab [45] and Grady et al.[46]. This allows us to remove the effect of potential digestive
absorptive differences between macrocarnivourous mammals and theropods from our data.
Regardless of whether these taxa were true truly endotherms or mesotherms, these values should
produce reasonable estimates of relative disparities in expenditures to compare between
specimens.
Results
Relative leg length
In comparing the relative hindlimb versus distal hindlimb indices while there is a correlation
between them, we also observe a disconnect between the two, notably in small to medium sized
theropods less than 1200 mm SVL (Supp. Table 1). This is especially clear when comparing
some contemporaneous taxa, such as compsognathids and microraptorines (Figure 1). The
former clade has been suggested to be highly cursorial while the latter were not based on
evaluation of the hindlimb index alone [14]. Our results dispute this finding, as well as previous
work that ignored allometric effects in comparing smaller compsognathids to mid-sized and
larger dromaeosaurs such as Velociraptor or Deinonychus[14]. Focusing on non-avian theropods,
as avian theropods have different hindlimb scaling factors compared to non-avian theropods
[15], we also negative allometric scaling in interlimb ratios which alone could influence
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comparison between these two clades. Even at similar sizes the divergence between relative
hindlimb versus distal limb metrics is clearly illustrated by comparing the Yixian biota
contemporaries Changyuraptor and Sinosauropteyrx, both of which are suspected small
carnivores that differ in length by 10mm (~ 2% total SVL). Changyuanraptor show a relative
hindlimb index of 0.96, which is significantly higher than that is seen in Sinosauropteyrx (0.57)
while showing a distal limb index value 8% lower. This pattern of high hindlimb indices whiles
showing relatively mild distal limb values is seen across all small bodied microraptorines and
basal troodontids, with the opposite trend seen in small bodied compsognathids and basal birds.
Interestingly, amongst anchiornithids (a clade of small bodied paravians who have recently
suggested to be more closely related to birds than either dromaeosaurids or troodontids [47, 48])
we see a diverse pattern of values ranging from Anchiornis at the high end (92-95%) to Caihong
(78%) at the lower end, though the latter is still similar to what is seen in the cursorial
oviraptorosaur Caudipteryx (0.75-0.79). We calculated maximum speed potential with the larger
hindlimb indices in many microraptorines allowing them to achieve higher top end speed
suggesting a sharp demarcation between burst speed potential between microraptorines,
contemporaneous small bodied compsognathids and basal birds (Figure 2, Sup. Table 2).
Depending on the speed estimator used Changyuraptor shows top speed between 5.13-7.98 m/s
which is 1.2-1.9 m/s (4.9-6.9 km/hr) higher than Sinosauropteryx using the same metric. We also
find that the juvenile tyrannosaur “Raptorrex” (a suspected young Tarbosaurus specimen [49]),
shows significant burst speed potential, even higher than similar sized ornithomimids,
oviraptorosaurs or basal tyrannosauroids (Sup. Table 2). This supports the idea that juvenile
tyrannosaurids were highly cursorial [9, 13, 14].
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To evaluate the general applicability of these various hindlimb rations across Theropoda as a
good proxy for top speed we compared distal limb index, hindlimb index as well as metatarsal
and whole leg length compared to body size using top speeds at FR=5 and under the mass
limiting top speed equation of [7]. Using the primary dataset (Sup. Table 3) we find that all
proxies have relatively low correlation value, with distal limb index (r2=0.55) as the only metric
showing a significant correlation when using speed based on Froude number. When we take into
account the limiting factor of increasing body mass, all metrics show precipitous decrease in
correlation value with none of them showing a significant relationship to speed (Figure 3, Sup
Table 3). To confirm this was not due to the taxon sampling we used our larger dataset (Sup.
Table 4), which though it did not allow us to evaluate HL/SVL, did allow for testing the other
three metrics. Using just Froude number all three metrics showed significant correlations to top
speed, with distal limb index showing the highest correlation (r2=0.48) (Figure 4, Sup. Table 5).
Once again, when correcting for mass all three metric correlations drop to insignificant levels,
with distal limb index showing a correlation coefficient of less than 0.04.
Energy consumption in theropods
To determine whether the greatest selection pressure for hindlimb elongation was a savings in
terms of transport costs or maximizing top speed, we compared top speeds calculated using Fr=5
or 15 to that accounting for body mass in our expanded limb dataset (Figure 4, Sup. Table 4).
Across all speed estimates we find that at lower size classes the estimated top speed is lower than
the theoretical maximum generated through [7]. However, this changes in mid to large size
theropods. Depending on the speed estimator used the body mass limiting top speed drops below
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the others at around 500 kg using a Fr of 15 and 2000kg using a Fr=5. This corresponds to a hip
height of ~ 1.5-2.1 m.
Using existing volumetric derived masses, we calculated the cost of transport across a range of
theropods and dinosauriforms from 0.25 kg to greater than 9000kg (Table 1). Our results show
that, among the large bodied theropods, tyrannosauroids show a significantly lower cost of
transport than comparable size more basal taxa, with differences most exacerbated in juvenile
and sub-adult size classes (Table 1, 2). If we hold velocity constant at 2 m/s, we see significant
differences in energetic values between tyrannosauroids and other large taxa (Table 2), based on
the relative elongation of their hindlimbs. In order to assess what level of difference in foraging
efficacy in terms of CoT make in terms of overall energy expenditure we reconstructed daily
energy expenditure budgets for tyrannosaurids and more basal theropods that differed from each
other by less than 3% of total body mass. While the differences in the cost of transport values
between tyrannosauroids and other large theropods may appear minimal, ranging from only 0.03-
0.62 j/kgm, when they are evaluated for taxa at these large sizes and over longer temporal
durations they produce significant differences (Table 3A, B). We chose to look at both basal
metabolic rate (BMR) and BMR + foraging costs to gain a baseline to compare relative
differences in energy use. This was done to ensure we would not produce an exaggeration of the
differences between taxa as, for example, the estimated dally caloric intake according to BMR
using [46] for the 660 kg juvenile tyrannosaurid “Jane” is only 2400 calories or about the same
as the lead author.
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We see significant differences between tyrannosaurids and more basal large theropods, using
either BMR or BMR + energetic expenditures for both the hourly and distance based foraging
ranges. Using a 12 daily hour foraging regime per [35] we find foraging savings between similar
sized tyrannosaurids and more basal forms is between 10% of daily to 300% of daily BMR
(Table 2, 3a). We contend this suggests that this metric may be too low a baseline. Using BMR +
energetic expenditure values we find differences drop, but the trends remain similar. Differences
in total daily expenditure range from 1.3% in the largest Tyrannosaurus specimens compared to
Giganotosaurus up to 35% when comparing the juvenile Tyrannosaurus “Jane” to a
Ceratosaurus (Table 3b). This translates to between 2-16kg of extra meat a day. Interestingly,
the highest values are seen when comparing Acrocanthosaurus (NCSM 14345) to the “Wankel”
Tyrannosaurs specimen (MOR 555 [currently USNM 555000 with the transfer of the specimen
to the National Museum of Natural History]), but is lower in the largest specimens examined
here.
Given the uncertainty on the percentage of the day spent foraging, using distance traveled may
provide us with a more robust comparison. Adult tyrannosaurids have been estimated to travel
perhaps 18 km per day in foraging [34] which at 2 m/s would correspond to 2.5 hrs of foraging
time, comparable to that seen in modern large terrestrial mammalian carnivores[21]. Over the
course of a year this would amount to large bodied theropods traversing over 6500 km. If we
examine distance traveled we see lower, but still significant, differences in energy expenditure
ranging from 0.9 to 19.8% of total expenditure over that distance (Table 3). While these
differences, around 1% in the largest theropods, may seem insignificant of the course of a year
they are the equivalent of 3-6 days of total energetic expenditures (BMR + daily foraging of
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18km). If we translate that to how many meals over the course of a year’s foraging, it translates
to over 170kg of less meat consumed in the largest specimens. This corresponds to the size of a
Ornithomimus or subadult Thescelosaurus [34] and up to 1250 kg in the “Wankel” specimen
compared to Acrocanthosaurus which is the equivalent of 5 Thescelosaurus.
Discussion
Getting up to speed
We find that using single, simple limb metrics, especially distal limb ratios, directly in judging
the “cursoriality” of taxa across Theropoda is not defensible unless supplemented with other
means of support. If looking at comparable sized individuals, particularly amongst small
theropods less than 500kg, using either HL/SVL or distal limb indices has the potential to allow
for accurate assessment of relative level of cursoriality between specimens, but given the low
correlation value generated in our analysis, caution is advised on using these as central pillars in
paleoecological reconstructions. One major reason for this is that some indices, such as HL/SVL,
are highly influenced by allometry. HL/SVL amongst non-avian theropods shows a strongly
negative scaling with body size (log HL=0.85293+/- 0.022505* log SVL+0.26446 +/- 0.063007,
r2=0.96, p(uncorr)>0.001, n=77). Thus larger animals, up until they hit the boundary where body
size limits speed and acceleration potential [7], will have higher absolute speeds due to their
absolutely longer leg length. Thus, at the same Froude number, they will have higher top speed
regardless of the proportions of the limb. For example, Eustreptospondylus (Hl=1209 mm,
HL/SVL 0.58, Distal limb index 1.43) has a higher top speed at a Froude of 5 (7.7 m/s) than
Changyuraptor (4.6 m/s, Hl=433 mm, HL/ SVL=0.96), Distal limb index 1.83. Distal limb index
also shows this pattern of negative allometry, though the correlation is weaker (Distal limb
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index=-0.41125+/- 0. 064192 *log SVL+3.0372 +/- 0.17972, r2=0.39, p(uncorr)>0.001, n=77)
which may explain why, without correcting for mass, it shows a significant relationship to top
speed.
It is clear when we take into account body mass there is an upper limit on running speed that
becomes more influential on the life history and ecology of theropods as one approach’s ~1000
kgs. This pattern fits with what is expected theoretical [50] and shown through empirical studies
[7, 20, 51]. While this size class only represent a fraction of theropod diversity [52] it represents
crucial mid to top level carnivores for much of the Mesozoic since the Early Jurassic [1, 15, 53].
This raises the questions of why certain groups, most notably the tyrannosaurids, elongate their
hindlimbs relative to more basal taxa when this costly addition, in terms of growth, was not
aiding in increasing speed as they had already maxed out their potential for that. We suggest as
one possibility that the likely selective pressure driving this was related to increasing foraging
ability or home range size by decreasing the energy spent during low speed locomotion over long
distance, as seen in extant taxa [20, 51]. Alternatively (and not mutually exclusive), they may
have simply retained this limb proportions from smaller-bodied ancestors or earlier ontogenetic
stages in which these proportions were adaptively significance in terms of increased speed [54,
55].
In many modern hunters, active searching for food does not occupy the entirety of their day [21,
22], though this does increase markedly in scavengers [35]. Of the time spent actively foraging
only a fraction of that is accounted for by high speed pursuit. For example, in African wild dogs
less than 8% of total hunt distance is traveled at high, yet not top, speed [56] and similar pattern
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seen in the amount of running stalking time seen in lions [57]. It is probable therefore that a
decrease in the ability to maximize speed would have not been a significant cost to larger
theropods, since much of their lives would likely have not been spent in the active pursuit of prey
at top speeds. Furthermore, the total energetic cost of hunting prey (pursuit, capture and killing)
in modern larger carnivores is notably higher compared to those who favour small prey [21].
We therefore infer that amongst theropods weighing over 1000kg, selection for energetic
efficiency was likely significant regardless of the interlimb proportions.
For smaller (<1000 kg) theropods the opposite conditions apply. Not only are they more likely to
be small prey specialist, where pursuits are short and prey easy to subdue, limiting the energy
losses during hunting. Yet just as importantly these organisms are themselves potential prey
items to larger theropods. This means that they have a strong selective pressure to obtain high
top speed, especially with a short acceleration time, to facilitate escape. Thus, we find two
opposing selective pressures across theropod hindlimb, one at small size to maximize speed
which decreases as you get larger to focus more on energetic savings in mid-sized to large
members of the theropod community.
Why tyrannosaurids?
In looking for the origins behind the trend of long leggedness in tyrannosaurids, and the potential
ecological and behavioural underpinnings for it, one must first determine if it a plesiomorphic
feature of a wider Tyrannosauroidea or even coelurosaurian condition. That the coelurosaur
condition is characterized by elongated hindlimbs is unlikely as other basal coelurosaurs such as
compsognathids show reduced hindlimbs, among the lower third of the dataset and though the
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tibia is incomplete Zuolong shows values closer to Deinonychus (59th) than Tanycolagreus.
While some basal tyrannosauroids do show elongated hindlimbs compared to femoral
circumference (Sup. Table 4,5) such as Guanlong (1st), Tanycolagreus (12th), and Moros (11th),
others such as the basal Coelurus (65th) or Dryptosaurus (42nd), the latter of the two is larger (>
1000kg) and closer to tyrannosaurines, ranks in the lower half. Additionally, if one were to
reconstruct the femoral circumference of Dilong from its femoral width it would rank in the
bottom quartile at around 64th. This combined with significant uncertainty due to the number of
partial specimens at the base of the tyrannosauroid tree as well as the potential for the
Megaraptora to be basal tyrannosauroids [58], paints an uncertain picture of how to reconstruct
the evolution of hindlimb elongation in this clade. What we can say is that all the small long-
legged basal members of this clade are well below the inflection point of selective pressures for
speed versus efficiency. As such their position as mid-level predators in their ecosystem who
were potential prey themselves could lead to species specific selection pressures being confused
with clade wide trends. Finally, as we do not have a good understanding of the size of basal
members of Tetanurae or Orinoides, though we suspect they were significantly smaller our cross
over point [2, 15, 59]. Without these fossils, we cannot assess if derived tyrannosaurs retained
the elongated hindlimbs of their small ancestors as they evolved gigantism or if this was a
secondary elongation event confined to the later members of Eutyrannosauria.
Despite this the fact that both subadult and mature allosauroids, tyrannosaurines and tetanurans
were too large to access upper range of speed due to their hindlimb length, raises the question of
why they differ so much in relative limb length. One potential explanation is difference in prey
choice. Sauropods were rare in those communities where Tyrannosauridae existed [60], with
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only a single taxon, Alamosaurus, known from North America restricted to the Southernmost
part of Tyrannosaurus’ range [61], and two (c.f. [62]) small sauropods from the Nemegt which
are minor members of the fauna [63]. For tyrannosaurids the most common larger prey taxa are
herds of ceratopsians and hadrosaurs which are on the order of 1/5-1/10 the mass of the sauropod
prey available to the larger allosauroids and basal tetanurans [52]. Furthermore, sauropods were
a ubiquitous component of the ecosystems of these more basal large theropods [64], presenting a
common and calorie dense meal source either through direct predation or carcass scavenging.
While it is likely that much of the prey captured for theropods were juvenile and subadult
specimens regardless of the prey species [65], sauropods would still provide a much larger meal
with many species with over 40% of the population consisted of individuals of 3500kg or more
[64]. In addition sauropod trackways indicate they tended to walk at slow speeds [66], and their
size alone strongly suggests they would have a limited top speed significantly below that of their
contemporaneous larger theropod faunas [7]. Thus, sauropods would provide an abundance of
larger, slower and more energy dense food resources for more basal large theropod clades.
Conversely we are suggesting that the pressure for obtaining more kills due to the fact that each
kill provides less resources, thus necessitating minimizing energy expenditure per hunt and
maximizing resource extraction per kill, especially if that kill is shared amongst a group,
influenced selection for longer limbs in Tyrannosauridae.
Hunting the relatively smaller and faster hadrosaurs and ceratopsians may also have been
facilitated by group behavior in tyrannosaurids, something previously documented by track and
body fossils in large theropods [38, 67]. Juveniles, less than 10-15 years of age [68, 69] would
still be in the zone where their long legs could be used to maximize top speed, potentially
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helping run down faster prey items. Beyond this it has been shown that amongst pack hunting
animals employing strategy or communication between individuals can allow them to capture
prey that is faster than any one individual [70]. Combining these factors we find that pack
hunting would only increase the energetic savings differential even more dramatic between
tyrannosaurs compared to allosauroids. For example, if we assume a tyrannosaur “pack”
consisting of two adults around the size of BHI 3033 or MOR 555 and two subadults with
femora approaching 1 m in length and 2500kg in mass and two juveniles the same size as “Jane”
the savings versus a similar sized and demographically distributed group of Acrocanthosaurus or
Saurophaganax is between 4000-4300kg worth of prey. This corresponds to about the mass of a
1-2 hadrosaurids [34] or 28-30 days of total energetics for the groups. If similar to modern large
terrestrial carnivores the majority of hunts end in failure with only a 20-30% success rate [21],
such a savings would reduce the necessity for multiple hunts, where during each on beyond the
loss of energy in a failed capture this there is the inherent risk from injury either during the
pursuit or capture itself. Such a large amounts of savings, corresponding to several large kills
per year, would have significant effect on survivorship of the group.
Finally, there is the fact that meat acquisition does not necessarily have to exclusively come from
the capture and killing of live prey items. Most modern primary predators and, likely, extinct
ones such as large theropods, probably incorporate a significant fraction of carrion into their diet
[35]. We know of several occurrences of likely scavenged tyrannosaurid feeding traces [65, 71,
72] indicating some facultative carrion usage did occur. Recent work [35] has estimated that
scavenging would have been most important to mid to large, but not extremely large, sized
theropods around the range that we find mass induced upper limits on top speed. While we may
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not agree with the assumptions and assertions of the level of scavenging suggested by [35], we
do suggest that this is another line of evidence of the increasing role of energy efficiency over
long distances locomotion. Given the data we have presented here saving multiple days’ worth of
feeding requirements due to reduced energetic demands by increased leg length in large
tyrannosaurids. Any adaptation that helps reduce the costly and potentially hazardous search,
capture, killing and defending a kill would be a significant evolutionary advantage for that
lineage and may have been one of the keys to their success in the Late Cretaceous c.f. [73].
Conclusions
Here we find that traditional simple metrics, notably the distal limb index, fail to reflect true
measures of cursorial and especially top speed potential across Mesozoic theropods. When direct
comparisons of similar sized individuals are performed several clades, most notably the
compsognathids and basal birds which show high levels of distal limb elongation, do not show
comparable total limb relative lengths or top speed to microraptorines or basal troodontids.
Without accounting for the allometric influence on any of these limb metrics we remain highly
skeptical of their broad application. Additionally we also show that when we include the fact that
there is a parabolic distribution of top speeds, with a local maxima between 500-2000kg
depending on the Froude number used to estimate speed, there is no significant relationship
between distal limb index (or indeed any other commonly used hindlimb index) and top speed
across theropods. We argue that selection for intralimb lengths is likely multifaceted, clade
specific and unlikely to be captured in a simply, overarching metric.
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Factors such as clade history, diet and prey capture methods, for example the role of the
hindlimb in subduing prey in eudromaeosaurs [74] likely has implication for why they tend to
have short metatarsals, all combine with speed and cost of transport influences to shape the final
product. Despite saying this we do propose that, at a first order of magnitude, we can argue that
there body size likely has a major role. Body sizes is here postulated to be strongly influential in
the shifting the speed versus endurance/ energy savings balance in the paleobiology of theropods.
Smaller taxa are more likely to take smaller prey, which reduces foraging and capture costs but
conversely are they themselves much more likely to predated upon. For them a fleet foot may be
the difference not just in a full or empty belly but in life or death. In larger taxa this balance
shifts to be more “waste not, want not” as they are much less likely to be hunted while they are
searching for prey.
We also find that amongst the large bodied theropods tyrannosaurids show markedly reduced
values of cost of transport due to their elongated limbs. While their body size makes this unlikely
to be of much value in increasing running speed, it does significantly save on the cost of daily
foraging expenditures. These savings, up to several tones of meat per year per individual, would
dramatically reduce the need to engage in the costly, dangerous and time-consuming act of
hunting. When coupled with the evidence that tyrannosaurids were, at least on occasion, living in
groups as well as the fact their primary prey was on average smaller and more elusive than the
sauropods that were a major component of the diet of more basal large theropods, this paints a
picture where efficiency would be a major evolutionary advantage. While we cannot clearly
ascertain if the “legginess” of tyrannosaurs was an adaptation itself or the retention of the
ancestral condition of elongated hindlimbs as gigantism evolved in this clade both options
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present interesting evolutionary scenarios with broader implications for the paleobiology and
paleoecology of the Late Jurassic to Late Cretaceous ecosystems of Laurasia.
Interestingly, additional analyses support the hypothesis that tyrannosaurids were more agile
(that is, capable of turning more rapidly and with a smaller turning radius) than other
comparable-sized large-bodied theropods [9]. This similarly reflects a specialization with
Tyrannosauridae for hunting large-bodied ornithischians such as hadrosaurids and ceratopsids
themselves likely more mobile and agile than sauropods. When combined these two lines of
evidence for an energy efficient, yet still nimble, design of the Tyrannosauridae hindlimb reflect
a likely long-distance stalker with a final burst to the kill likely in a pack or family unit, similar
to modern wolves. This further reinforces the notion, that beyond being the apex predator of the
latest Cretaceous Laurasian ecosystems, the tyrannosaurids were amongst the most accomplished
hunters amongst large bodied theropods. We find that their anatomy, at once efficient and
elegant, yet also capable of burst of incredible violence and brute force, lives up to their
monikers as the tyrant kings and queens, of the dinosaurs.
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Table 1: Specimens used for costs of transport analysis based on published 3D volumetric data.
HL stands for hindlimb length which here is taken as femur + Tibia + central metatarsal lengths.
HH is hip height, calculated as 0.8*HL. CoT is cost of transport, see text for details.
Source Taxon Specimen Mass (kg) HL (mm) HH (cm) CoT
Bates et al. 2009 Struthiomimius BHI 1266 423 1800 144.0 1.97
Bates et al. 2009 Allosaurus MOR 693. 1500 1699 135.9 2.06
Bates et al. 2009 Tyrannosaurus MOR 555/USNM 555000 6072 3036 242.9 1.31
Bates et al. 2009 Acrocanthosaurus NCSM 14345 6177 2675 214.0 1.45
Bates et al. 2012 Tyrannosaurus BHI 3303 7655 3196 255.7 1.26
Pontzer et al. 2009 Archaeopteryx MB.Av.101 0.25 158 12.6 12.80
Pontzer et al. 2009 Marasuchus Composite 1.00 170 13.6 12.10
Pontzer et al. 2009 Microraptor IVPP V13352 1.20 291 23.3 8.00
Pontzer et al. 2009 Compsognathus BSP AS I563 3.00 209 16.7 10.32
Snively et al. 2018 "Raptorex" LH PV18 47 998 79.8 3.10
Snively et al. 2018 Eustreptospondylus OUM J13558 206 1245 99.6 2.61
Snively et al. 2018 Dilophosaurus UCMP 37302 372 1412 113.0 2.37
Snively et al. 2018 Gorgosaurus TMP 91.36.500 496 1825 146.0 1.95
Snively et al. 2018 Tyrannosaurus BMRP 2002.4.1 660 2120 169.6 1.73
Snively et al. 2018 Ceratosaurus USNM 4735 678 1429 114.3 2.35
Snively et al. 2018 Gorgosaurus AMNH 5664 688 1928 154.2 1.87
Snively et al. 2018 Tarbosaurus ZPAL MgD-I/3 727 1845 147.6 1.93
Snively et al. 2018 Allosaurus USNM 4734, UUVP 6000 1512 1985 158.8 1.82
Snively et al. 2018 Allosaurus MOR 693 1683 1795 143.6 1.97
Snively et al. 2018 Yangchuanosaurus CV 00215 2176 1988 159.0 1.82
Snively et al. 2018 Sinraptor ZDM 0024 2374 2340 187.2 1.61
Snively et al. 2018 Gorgosaurus AMNH 5458 2427 2640 211.2 1.46
Snively et al. 2018 Gorgosaurus NMC 2120 2427 2634 210.7 1.47
Snively et al. 2018 Tarbosaurus PIN 552-1 2816 2415 193.2 1.57
Snively et al. 2018 Acrocanthosaurus NCSM 14345 5474 2676 214.1 1.45
Snively et al. 2018 Giganotosaurus MUCPv-CH-1 6908 3020 241.6 1.32
Snively et al. 2018 Tyrannosaurus CM 9380 6987 3124 249.9 1.29
Snively et al. 2018 Tyrannosaurus FMNH PR 2081 9131 3261 260.9 1.24
Person and Currie 2014 Khaan MPC-D 100/1127 5 391 31.3 6.37
Person and Currie 2014 Velociraptor MPC1--/986 15 592 47.4 4.63
Person and Currie 2014 Ajancingenia MPC-D 100/30 17 634 50.7 4.39
Person and Currie 2014 Ornithomimus TMP 95.11.001 150 1220 97.6 2.65
Person and Currie 2014 Gorgosaurus TMP 91.36.500 400 1815 145.2 1.95
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Person and Currie 2014 Tyrannosaurus BHI 3303 5622 3196 255.7 1.26
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Table 2: Foraging coasts amongst large bodied theropods based on volumetric reconstructions.
A) costs in Kj on an hourly, daily and yearly basis. B) Costs of foraging in Kj per unit distance
assuming a 18km daily foraging distance as per Carbonne et al (2011) for 1Km, 1 day (18 Km)
and 1 year (6570Km).
A)
Foraging 12 hrs/ day
Taxon specimen Mass (kg) HL (mm) HH (cm) CoT hr day year
Tyrannosaurus MOR 555 6072 3036 242.9 1.31 57481 689771 251766250
Acrocanthosaurus NCSM 14345 6177 2675 214.0 1.45 64462 773541 282342590
Tyrannosaurus BHI 3303 7655 3196 255.7 1.26 69657 835879 305095703
Tyrannosaurus BMRP 2002.4.1 660.23 2120 169.6 1.73 8241 98892 36095640
Sinraptor ZDM 0024 2373.5 2340 187.2 1.61 27457 329487 120262751
Gorgosaurus AMNH 5458 2427.3 2640 211.2 1.46 25589 307067 112079592
Gorgosaurus NMC 2120 2427.3 2634 210.7 1.47 25634 307606 112276127
Tarbosaurus PIN 552-1 2816.3 2415 193.2 1.57 31798 381573 139274251
Acrocanthosaurus NCSM 14345 5474.1 2676 214.1 1.45 57110 685320 250141950
Giganotosaurus MUCPv-CH-1 6907.6 3020 241.6 1.32 65658 787893 287580837
Tyrannosaurus CM 9380 6986.6 3124 249.9 1.29 64700 776397 283384765
Tyrannosaurus FMNH PR 2081 9130.87 3261 260.9 1.24 81808 981697 358319261
Tyrannosaurus BHI 3303 5622 3196 255.7 1.26 51157 613888 224068980
B)
Source Taxon specimen mass (kg) per km 18 km 6570 km
Bates et al. 2009 Tyrannosaurus MOR 555 6072 7983 143702 52451302
Bates et al. 2009 Acrocanthosaurus NCSM 14345 6177 8953 161154 58821373
Bates et al. 2012 Tyrannosaurus BHI 3303 7655 9675 174141 63561605
Snively et al. 2018 Tyrannosaurus BMRP 2002.4.1 660.23 1145 20603 7519925
Snively et al. 2018 Sinraptor ZDM 0024 2373.5 3814 68643 25054740
Snively et al. 2018 Gorgosaurus AMNH 5458 2427.3 3554 63972 23349915
Snively et al. 2018 Gorgosaurus NMC 2120 2427.3 3560 64085 23390860
Snively et al. 2018 Tarbosaurus PIN 552-1 2816.3 4416 79494 29015469
Snively et al. 2018 Acrocanthosaurus NCSM 14345 5474.1 7932 142775 52112906
Snively et al. 2018 Giganotosaurus MUCPv-CH-1 6907.6 9119 164144 59912674
Snively et al. 2018 Tyrannosaurus CM 9380 6986.6 8986 161749 59038493
Snively et al. 2028 Tyrannosaurus FMNH PR 2081 9130.87 11362 204520 74649846
Person and Currie 2016 Tyrannosaurus BHI 3303 5622 7105 127893 46681037
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Table 3: A) Cost of transport during daily foraging during and energy expenditure calculated
using basal metabolic rate (BMR) estimates per [45, 46] in Kj. B) Comparison of daily energy
expenditure (foraging + BMR) between Tyrannosauridae and similar sized basal large bodied
theropods.
A)
Source Taxon specimen mass (kg) HL CoT Foraging BMR [45] BMR[46]
Snively et al. 2018 Tyrannosaurus BMRP 2002.4.1 660 2120 1.73 98892 20270 10226
Snively et al. 2018 Ceratosaurus USNM 4735 678 1429 2.35 137647 20676 10454
Snively et al. 2018 Gorgosaurus AMNH 5664 688 1928 1.87 110818 20887 10573
Snively et al. 2018 Sinraptor ZDM 0024 2374 2340 1.61 329487 51915 29199
Snively et al. 2018 Gorgosaurus AMNH 5458 2427 2640 1.46 307067 52778 29740
Snively et al. 2018 Gorgosaurus NMC 2120 2427 2634 1.47 307067 52778 29740
Snively et al. 2018 Acrocanthosaurus NCSM 14345 5474 2676 1.45 685320 95950 57938
Person and Currie 2016 Tyrannosaurus BHI 3303 5622 3196 1.26 613888 97848 59218
Bates et al. 2009 Tyrannosaurus MOR 555 6072 3036 1.31 689771 103546 63078
Bates et al. 2009 Acrocanthosaurus NCSM 14345 6177 2675 1.45 773541 104859 63971
Snively et al. 2018 Giganotosaurus MUCPv-CH-1 6908 3020 1.32 787893 113839 70112
Snively et al. 2018 Tyrannosaurus CM 9380 6987 3124 1.29 776397 114794 70769
B)
total daily (basal + 12 hours walking) 18 km + daily BMR
Taxon specimen BMR [45]
% difference
BMR[46]
% difference.
BMR [45]
% difference
BMR[46]
% difference
Tyrainnosaurus BMRP 2002.4.1
119162 32.5 109118 35.5 40873 19.8 30828 26.2
Ceratosaurus USNM 4735 158323 x 148101 x 49352 x 39131 x
Gorgosaurus AMNH 5664 131705 20.4 121392 22.1 43974 12.7 33660 16.6
Sinraptor ZDM 0024 381402 x 358686 x 1205583 x 97842 x
Gorgosaurus AMNH 5458 359845 6.2 336808 6.7 116750 4.0 93712 5.0
Acrocanthosaurus
NCSM 14345 781270 x 743258 x 238725 x 200713 x
Tyrannosaurus BHI 3033 711736 10.0 673106 10.6 225741 6.6 187111 8.0
Tyrannosaurus MOR 555 793316 x 752848 x 247248 x 206780 x
Acrocanthosaurus
NCSM 14345 878400 9.5 837512 10.0 266013 6.6 225125 7.8
Giganotosaurus MUCPv-CH-1
901731 x 858005 x 277983 x 234256 x
Tyrannosaurus CM 9380 891191 1.3 847165 1.4 276543 0.9 232518 1.0
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Figure Captions
Figure 1: Comparison of two small bodied theropod clades, the compsognathids and
dromaeosaurids, using different hindlimb indices purported to be associated with cursorial
ability. Note the significant difference in how the running ability and top speed would be
reconstructed depending on the metric selected. Using relative hindlimb length (A) we find a
significant difference between the two groups (unequal variance t-test 5.1471, p=0.001) and
would reconstruct dromaeosaurids as significantly faster than compsognathids. Using distal limb
index (B) we see no difference between clades (unequal variance t-test 0.7713, p=0.45).
Silhouette modified from those in Phylopic image repository (Phylopic.org) created by Joh
Conway and Brad McFeeters.
Figure 2: Top speed comparison between clades using speed calculated from equations in [28],
though all reconstruction methods show similar patterns, either including (A) or excluding (B)
Halszkaraptor based on its proposed unique semi aquatic lifestyle. Note that at lower speeds the
dromaeosaurs, more specifically microraptorines, show distinctly higher top speed than
comparably size compsognathids, Archaeopteryx specimens or basal birds and similar values to
troodontids. Silhouette modified from those in Phylopic image repository (Phylopic.org) created
by Joh Conway, Matt Martynuik, Gareth Monger and Brad McFeeters.
Figure 3: Evaluation of the fit of hindlimb index proxies to estimated top speed at Froude=5 (A)
and using the mass induced limitation as proposed in [7] using the primary dataset of taxa with
SVL data. Skeletal image of Microraptor modified from the illustrations of S. Hartman.
also made available for use under a CC0 license. not certified by peer review) is the author/funder. This article is a US Government work. It is not subject to copyright under 17 USC 105 and is
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Figure 4: Evaluation of the fit of the distal limb index proxy to estimated top speed at Froude=5
(A) and using the mass induced limitation as proposed in [7] in the larger hindlimb dataset (Sup.
Table 4). Skeletal image of Microraptor modified from the illustrations of S. Hartman.
Figure 5: Observing the effect of increasing body mass on top speed in non-avian theropods by
evaluating the difference between various reconstructive methods. Note that at smaller body size,
less than 100 kg, there is a large and increasing gap between the top speed limit imposed by [7]
and top end estimates from other methods. This gap becomes largest in specimens between 10-
100 kg indicating that perhaps these specimens had the highest ceiling to increase running speed
by exaggerating hindlimb muscle size, altering insertion location, moment arm length, total leg
length or stride frequency. Silhouette modified from those in Phylopic image repository
(Phylopic.org) created by Joh Conway, Scott Hartman, Emily Willoughby and Matt Martynuik.
also made available for use under a CC0 license. not certified by peer review) is the author/funder. This article is a US Government work. It is not subject to copyright under 17 USC 105 and is
The copyright holder for this preprint (which wasthis version posted September 27, 2019. ; https://doi.org/10.1101/785238doi: bioRxiv preprint
also made available for use under a CC0 license. not certified by peer review) is the author/funder. This article is a US Government work. It is not subject to copyright under 17 USC 105 and is
The copyright holder for this preprint (which wasthis version posted September 27, 2019. ; https://doi.org/10.1101/785238doi: bioRxiv preprint
also made available for use under a CC0 license. not certified by peer review) is the author/funder. This article is a US Government work. It is not subject to copyright under 17 USC 105 and is
The copyright holder for this preprint (which wasthis version posted September 27, 2019. ; https://doi.org/10.1101/785238doi: bioRxiv preprint
also made available for use under a CC0 license. not certified by peer review) is the author/funder. This article is a US Government work. It is not subject to copyright under 17 USC 105 and is
The copyright holder for this preprint (which wasthis version posted September 27, 2019. ; https://doi.org/10.1101/785238doi: bioRxiv preprint
also made available for use under a CC0 license. not certified by peer review) is the author/funder. This article is a US Government work. It is not subject to copyright under 17 USC 105 and is
The copyright holder for this preprint (which wasthis version posted September 27, 2019. ; https://doi.org/10.1101/785238doi: bioRxiv preprint
also made available for use under a CC0 license. not certified by peer review) is the author/funder. This article is a US Government work. It is not subject to copyright under 17 USC 105 and is
The copyright holder for this preprint (which wasthis version posted September 27, 2019. ; https://doi.org/10.1101/785238doi: bioRxiv preprint